Wrapping-machine.



A. P. HOLDEN & P. MORGAN. WRAPPING MACHINE.

APPLIGATION FILED JULY 23, 1912. RENEWED JULY 22, 1913.

Patented J an. 27, 1914.

l4 SHEETS-SHEET 1.

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.ylweivlbrs. MM/W Patented Jan. 27, 1914.

WRAPPING MACHINE.

APPLIUATION FILED JULY 23, 1912. RENEWED JULY 22, 1913.

A. P. HOLDEN & P. MORGAN.

)Yihwsses.

Zea

A. P. HOLDEN & P. MORGAN.

WRAPPING MACHINE.

APPLICATION FILED JULY 23, 1912. RENEWED JULY 22, 1913.

Patented Jan 27, 1914 Mom c 011A A. P. HOLDEN 6: P. MORGAN.

WRAPPING MACHINE. APPLIOATION FILED JULY 23, 1912. RENEWED JULY 22, 1913.

Patented Jan. 27, 1914.

14 BHEETS-SHEET 4.

MA/W/ m a W Wifiwsses Z W @M M A. P. HOLDEN & P. MORGAN. WRAPPING MACHINE. APPLICATION FILED JULY 23, 1912. RENEWED JULY 22, 1913.

1,085,260. Patented Jan. 27, 1914.

9 14 SHBBTSSHEET 5.

llllllllllll h ifiwssos. a\ .jnvullilrs A. P. HOLDEN 6: P. MORGAN. WRAPPING MACHINE. APPLICATION FILED JULY 23, 1912. RENEWED JULY 22, 1913.

1,085,260. I Patented Jan. 27, 1914.

14 SHEETS-SHEET!!- WRAPPING MACHINE. APPLICATION FILED JULY 23, 1912. gmmwnn JULY 1,085,260.

A. P. HOLDEN & P. MORGAN.

4JJPJQ G 6 Z n h 4 l Z p 9 m A. P. HOLDEN & P. MORGAN.

WRAPPING MACHINE.

AIYLIOATION FILED JULY 23, 1912. RENEWED JULY 22, 1913.

Patented Jan. 27, 1914.

14 SHEETS-SHEET 8.

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m 7 w a; 5f '5 v! I" y z l H M 9 I 4. Zji 11.

P- a t v a MW A. P. HOLDEN & P. MORGAN.

WRAPPING MACHINE.

APPLICATION FILED JULY 23, 1912. RENEWED JULY 22, 1913.

1,085,260. Patented Jan. 27, 1914.

14 {BEETS-SHEET 9.

A. P. HOLDEN & P. MORGAN. WRAPPING MACHINE.

APPLICATION FILED JULY 23, 1912. RENEWED JULY 22, 1913.

1,085,260. Patented Jan. 27, 1914.

14 SHEETS-SHEET 10.

h i'liussw. Jnwdbrs.

A. P. HOLDEN & P. MORGAN.

WRAPPING MACHINE.

APPLICATION FILED JULY 23, 1912. RENEWED JULY 22. 1913.

Patented J an. 27, 1914.

14 SHEETS-SHEET 11.

A. P. HOLDEN & P. MORGAN.

' WRAPPING MACHINE.

APPLICATION rum) JULY 23, 1912 RENEWED JULY 22, 1913.

1,085,260, I Patented Jan. 2'7, 1914.

14 SHEETSSHEET 12.

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A. P. HOLDEN & P. MORGAN.

WRAPPING MACHINE.

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WRAPPING MACHINE. APPLICATION FILED JULY 23, 1912. RENEWED JULY 22, 1913. 1,085,260.

Patented Jan. 27, 1914.

14 SHEETS-SHEET 14.

i ments in Wrapping-Machines; and we hereabove the movable initial'folder so that the where a presser'places a tension on it, and 4 holds the wrapper in its set position, while folds.

.and the other of which is relatively stasides of theloaf and prepaid for the formation 0 UNITED. STATES PA an'rnnn PnAnr HOLDEN Ann rm noncnn, or Tonomo, onzrfomana,

ASSIGNOBS TO THE nonnnn-nonoan comm, or rononro, on'mmo,

CANADA, A CORPORATION OF ONTARIO.

memo-mam.

s ecification of Letters Patent. Patented Jan. 27', 1914.

Application filed July as, 1912, Serial no; 711,o;o., Renewed m 22', 1e13 serial mil ra ars.

To all whom it may concern Be it known that we, ARTHUR PEABT Honor-2x and PHILIP Monoix. of the city of Toronto, in the county of York and Province of Ontario, Dominion of Canada, have invented certain new and useful Improveby declare that the following is a full, clear, and exact description of the same.

This invention relates to a wrapping machine. in which the articles to be wrapped are successively and intermittently delivered to the feeding carriage across the path of. which wrapping paper is fed from a roll and cutinto wrappers of predetermined length. For example, in the'case of a breadwrapping machine the loaves, preferably conveyed by a continuous carrier from the ing carriage which, as it moves to the folding mechanism. carries the loaf and the wrapper past the initial folders, and forms the wrapper to three sides of the loaf. These initial folders, one of which is movable across the path of the feedih carriage tionary then draw the wrapper tightly around the loaf and spread it smoothly across the fourth side before the artly formed wrapper is engaged by the on V folders, thus completingthe wrapping of four the wrapper folds. Two tly the en lifters then operate to raise the loaf sligh latter can return to its stationary position without loosening the wrapper, and then descend and allow the loaf torest upon a table the end folds are being formed. The end folders, which are timed to move in unison with the feeding carriage as it brings the succeeding loaf into operative relation with the initial folders, then enga V the ends of the partly formed wrapper 0 the preceding leaf and complete the formation of the end When the end folds are made, creasers come into action antler them,

and the end folds areflthen closed against the ends of the package to effect the sealing thereof, thls'creasihg being neoemaryfor the reason that highly calendered papers before being creased have sutlicient spring to make the end folds spread and tear the sealing apart. I,

"Figure 1, is a side elevation of a wrapping machine constructed according to our prlnciple, Fig. 2, is a plan view of 'the same; Fig. 3. is a broken section showing the parts of the folding mechanism in normal position; Fig. 4. is a similar view to Fig.3, with the parts in their foldin position; Fig. 5, is a sectional detail showing the paper severing mechanism and the feedin carriage the parts in this view being in t eir normal position; Fig. 8, is aview of the same con-- struction shown in Fig. 5 with the parts in" 1 their actuated positions; Fig. 7, is a sechtional detail showing the feeding carriage recedin to the position where it receives the loaves m the carrier, the wrapper being shown in this view as formed around three sides of the package; Fig. 8, is a similar view to Fig. 7 with thefeeding carriage omitted and the package moved to the position where" the end folds are made, the wrapper being shown in this view folded across thefonrth side; Fig. 9, shows the end 5 folders in position preparato? to completing the formation of the end olds; Fig. 10, is a similar view to Fig. 9, with the formation of the end folds completed; Fig. 11, shows the means for pressing the gummed edges together and creasing the folds so that they can be turned to lie against the oath of the-package; Fig. 12, is a plan view showing part of the drive for the intermittent paper feed; Fig. 13, is a b side eleva-- tion, of the gear and clutch for the intermittent pa r feed shown in Fig..12,when 96 the, parts are just declntched; 14, is I a vertical section-on the line H ig. 13; Fig. 15, is a side elevation of the same parts shown in Fig. 13, with the clutch rengnged; Fig. 16, is a detaiLo-f part of the clutch shown in Figs. 13, 14 and 15, with the clutch partsintheposition shown in Fig.1.); Fig. 17, IS a detail of the cam and levers controlling the transfer carriage; Fig. 18, is a vertical section of the line 31- 2; Fig. 17 Fig. 19, is 105 a plan view of the mechanism for pre ing used for the gummcd edges of the Fig. 21, is a sectional view of the feeding and gumming mechanism; Fig. 22, is a detail view showing the means for imparting lateral movement to the end folders during their lengthwise movement; Fig. 23,. is a perspective view of one of the side supports for the loaf when advanced by riage paper the feeding carriage for delivery to the loaf Fig. 24, is a side elevation of the means for holding the end folds,

supporting table;

\V'hile, for the purpose of explaining the principle of our apparatus, its constructive details and mode of operation, we have in the following specificatlon and accompanymg chine suitable for bread-wrapping purposes,

this being one of the essential uses and objects of our invention, we wish it to be understood that a machine comprising essentially the same combination of parts can be the wrapping ofother articles, and that in the case of articles of relatively small size, it maybe necessary to increase the number of folding units and the timing of their operation, to obtain a satisfactory output.

In the wrapping of bread, it has heretofore been customary to use waxed paper delivered through the folding mechanism to the place where the final folds are sealed by' the adhesive qualities of the wax when heated and pressed againstthe package ends. \Ve might state that in this class of paper, it has also been customary to wax the entire surface. from edge to edge, and that owing to the repellent nature of the wax, it has been impossible to gum any part of the surface thereof, and that during a series of exhaustive experiments with the use of this material, we concluded to have waxed paper specially made, leaving an'.unwaxed margin along each lengthwise edge which could be gumrned as the paper passes from the paper roll to the wrapping mechanism. Experience, however, proved several facts adverse to the use of this class of material for wrapping purposes (a) The cost of waxed paper, at prevailingrprices, is at least four times that of unwaxed paper, and this increased cost is a material factor governing the wrapping of the articles; (6) The moisture retaining properties of waxed paper for bread end folds together; 'Fig. 20, is a plan view of the transfer cardrawings, described and shown a ma .of the sprocket cchain f.

wrapping purposes where the bread is for immediate consumption or for consumption within a short period after baking, is relatively no greater than that of Well calendered unwaxed paper; and Unless a speciallymade waxed paper with unwaxed margins is used, its non-absorbent and liquid repellent character, renders -it a practical impossibility to gum it for fold sealing purposes, and that it is necessary to depend upon the adhesive qualities of the wax for the sealing thereof, which has not been sati'sfactory, as proper adhesion is dependent on thermostatic conditions- To overcome these and other objections to the use of waxed paper,.we have so designed our machine that we canuse an unwaxed paper and gum it as we feed it from the paper roll a to the. paper severing mechanism hereinafter described. W e'have also found it impractical to unwind the paper from the paper roll a by an alternate stopping and starting of the-feed rolls and the varied tension of the paper, tend to tear it when the feed motion starts. To obviate this trouble, we have provided intermittent-feed, as the the machine with a suitable drive to cong tinuously unwind the paper frqm the paper roll, this drive consisting of two feed rolls 1) and 0, between which the paper 0. passes from the paper roll a. One of these feed rolls b is provided with a sprocket wheel 03,

around which travels a continuous sprocket chain f driven byfa sprocket I cam shaft h. The revolution of the cam shaft 72. is continuous, and consequently a continuous revolution of the feed'roll b is effected through the continuity of the revolution of the sprocket wheel 9 and the travel This co tinu'ous revolution-of the feed roll I) is transmitted to the feed roll aby means of a suitable gearing. e, and the feed rolls 1; and 0 during their revolution, draw the paper forward from the paper roll, the paper passing from the feed rolls under a tension bar '1', to thegumming mechanism hereinafter described. The tension bar 71 is movable in slotted standards y'rising to the top of the standards as the paper is carried forward by the inter- \m1t tent feeding mechanism, hereinafter described, and descending to the bottom of wheel 9 on the the standards to stretch out the slack in the paper, created by the continuously rotating feed rolls when the action of the "intermittent feeding mechanism'ceases. This intermittent feeding mechanismconsists of a feed roll k provided with a sprocketwheel' l, a stud we provided with a sprocket wheel 0, a sprocket chain 17 passing around said sprocket wheels 1 and 0, and a suitable gear ingfor driving the same, intermittently driven from the cam shaft 'h. This gearing may be described as consisting of a pinion united revoluble with the sprocket wheel 0,

and meshing with the intermittently revoluble spur wheel 1- loosely mounted upon the hub 8 of the spur wheel t. The perimeter of the hub is a true circle, but the bore of the spur wheelr has two eccentric recesses u, u to permit of the oscillating movement of the driving dog 1; as it is pressed into and out of engagement with the shoulders u, w. These driving shoulders 10, 'w' are formed at-the forward end of the eccentric recesses u. 11' respectively and the driving dog 2' is pivoted within the hub s so that,

at the proper time it will be pressed by the spring :2 into engagement with the operative driving-shoulder.

The spur wheel t meshes with the driving pinion y on the driving shaft 2 and is continuously revolved thereby. The hub s is an integral partof the spur wheel 1, and the driving dog r bein pivoted in the hub and being carried there y, as a consequence, continuously revolves with said spur wheel. Fixed to the standard v is a roller 0' so positioned that when the spur wheel 2? has completed its revolution it will engage a trip dog (1' connected with the driving. dog r. and, by bearing against the trip dog, disengage the driving dog from the then operative driving shoulder, and when thedriving dog is so disengaged. the spur wheel 1 makes a further half-revolution to bring the driving dog '1: into operative relation with the next operative driving shoulder. In this way. the driving dog 1*, during the revolution of the spur wheel t, will carry the spur wheel r with it for one-half a revolution, then the driving dog will be disengaged from the operative driving shoulder, and the Plll wheel t will complete the other half of its revolution and bring the driving dog at into engagement with the. other driving shoulder. which, when so engaged, will move the spur wheel r. the remaining half revolution to complete its cycle of motion, when the driving dog 2 will again be from the then operativedriving shoul er. This action may be summarized by stating that it is possible to obtain an intermittent .motion of the spur wheel aduring the continuous motion of the spur wheel 25, and in the example illustrated in Figs. 13, 14, 15

and 16. it is possible to drive the spur wheel.

r one half a revolutiom'and to permit it to remain idle for the remaining half'revolution. of the spur wheel t.

To prevent the overrun of the spur wheel 1- when its semi-revolution is completed, and thus correctly determine the length of the wrapper, we rovide a spring-tensioned dog r pivoted on the stud 8 projecting from the main frame 111, and we so arrange the point of the dog that it will come into position shoulder t can clear it when the spur wheel .I' again starts its rotation, we provide the dog 1" with a roller u engaging a cam -11 on the spur wheel t. The cam v has two raised surfaces which as the spur wheel t rotates, successively engage the roller u and tilt the dog at the commencement of each semi-revolution of the spur wheel 1' into the raised position shown in Fig. 15.

hen the spur wheel 1' is driving, it rotates the pinion q and sprocket wheel 0, and causes the travel of the s rocket chain 1) and the rotation of the sproc et wheel 1 and feed roll k, which intermittently feeds the paper, the intermittent feed being taken from the slack resulting from the continuous feed previously When the intermittent feed starts up, the

j, and then, when the intermittent feed stops the tension bar descends to the bottom of the slot-ted standard, and tensions the slack bears ntpon the paper as it passes over the of e intermittent feed roll ll: and keeps the paper tightly in contact with that part of the intermittent feed roll it which it is at the timeengaging, so thabthe paste or gum can be evenly distributed to a the gummed. parts of the surface by the gumming mecha nism. This gumming mechanism, as shown in Figs. 2 and 21, consists of two paste dishes it supported at suitable positions below the path 0 the paper, and revoluble in the paste dishes k are the paste rolls 2".

naled in the paste dishes and driven from the intermittent feed roll is by a suitable gearing k. This gearing ktralso drives a shaft Z, upon which arefixed the gummers m1. These gummers m may be metal segments or they may be continuous disks, and during the intermittent feed of the paper they take the paste from the paste rolls 2" and apply it to the surface of the paper to be gummed.

The gummers m receive the paste from the paste rolls 2", and transfer it to the paper as it passes over the feed roll k, during the with'a shoulder t? on the spur wheel r, the i revolution of the shaft 2'. and these gummers spur wheel 7* bein provided with two of i when of a segmental character, as shown in these shoulders at diametrically opposite Fig. 2

are of sutlicient segmental length to I The paste rolls i are mounted on the shaft 7" jour- I V 1 V L gum only that partof the fold which is 'required to be sealed and thus economize the use of the paste and prevent trouble arising through the adhesion of the folds where it would be a disadvantage to apply the paste. '1 From the feed rolls k and g, the paper passes between the blades of the shears operated 'by a suitable link and crank con- The rock lever connection 7" from a cam s" on the cam shaft 71, and this motion is so timed that the paper starts to feed across the pathof the feeding carriage as the latter recedes to its normal position and the feed of the paper ends when the feeding carriage again starts on its upward course as hereinafter described, the earn 5-" then operating by means of thecrank, link and lever connection 1" and crank and link connection p to operate j wrapper lying on the paper "sup -6 the opposite side of it to the conveyer, isa

the shears to sever the paper.

The paper after feeding between the -blades of the shears 0, passes across the chine, tinuous ,COIIVQYGI'RG,

corrugated cones t having paper supports d", e, which hold it above the top of, the loaf being delivered to the feedingv carriage. This brings the paper into positionto be engaged by the top of the loaf as the feeding carriage ascends.

lVe have now described'the paper feeding, gumming,.and severing mechanisms, but Y before closing thispart of our description,

it might be stated that a convenient means for holding the paper roll is that shown in consisting of the their mandrels y, journaled on the frame 1: and. controlled by a friction clamp :12.

Before the Fig. 2 of the drawings,

ovens or cooling room to the WM ping maand for this purpose we use a conordinary type, and preferably drive it from the pulley b on the driving shaft 2. The loaves are delivered from the ovensor cooling room to the belt of the conveyer a and are carried forward by the conveyer belt to a position contiguous to the feeding carriage a where they are arrested by an escapementf intermittently actuated by a gear 9 from the driving shaft 2; the escapement and the driving gear being so timed that only one lo af will be delivered to the feeding carriage when at its normal position at each complete cycle of actionof the machine. 1

The loaves move in the direction indicated by arrow in Fig. 4, and are carried forward by the conveyer belt toward the feeding carriage, and would, if no provision was made to arrest their movement; crowd the foremost loaf into the path of the feeding ear- -riage before the proper time.

bread can be wrapped, it is necessary to convey the loaves Igfrom the which maybe of any underside of i i 5: escapement f to arrestthe foremostloafi;

and consequentlysall pressing againstit until the proper time for the"delivery ofthe foremost loaf to the feeding carria e, and y when the delivery of the foremost oaf to the feeding carriage is effected, the next loaf moves forward to the position occupied by' the preceding one-"for delivery to the feed- I ing carriage on the next cycle of action.

The feeding carriage 0" is supported by two guide rods h vertically -movable through the guide collais z'*,' secured to'the" .main frame v (see Figs. 3 and 22), as the feeding carriage tra'vels om its normal position to the initial folders, and returns; again to its normal position. At the sides of the. feedingcarriage c"! are upright plate 7', to maintain the loaf in.

a fixed position n the feeding carriage, this position being in direct relation withthe ports d'f, posed to the feeding carriage 0"v on' stopping plate g which ends the travel of the loaf from the conveyer, the stopp'ingJgg plate g" being shown in Fig. 3 as forming part of the paper support d By the use of the stopping plate 9" and; the uprightfplates j; the loaf can be co'rirectly centered with regard to the wrapper 9 on the paper supports d", e, which owing to its'fixed path, controlled by the feed ro'lls hereinbefore described, must.- necessa-rily be correctly delivered to the-paper supports each operation of the paper feeding mocha:- 109 nism. The feeding carriage, in its normal posietion as shown in Fig. 3, is below the level of the paper supports d", e", and in this posi' tion it receivesthe loaves from the conveyer. 5 'When the conveyer has delivered a loaf the feeding carriage c", the cam 72/ re'volyes5 and by means of a bell crank i",'raises,the feeding carriage toward the initial folders,.," hereinafter described.

The feeding carriage and the loaf sup-w ported thereon, then use in the direction in'-. dicated by arrow in Figs. 3 and 5, and as the carriage rises, the lower paper grips j, (see Fig. 7), come into contact wi 11 the 5' the wrapper and'carry it-upward until they meet the upperpaper grips v k slidably contained in guides .1" conveniently supported from the main frame u". (see Fig. 6). --These paper grips then 2 ,i'

above. the top of the loaf, and consequently 51;. I

elevate the underside of the wrapper slightly above it during the upward course of the.

feeding carriage. j

When the feeding carriage has attained its'limit of motion and the lower paper? grips have pushed the upper paper grips with the loaf,as shown in Fig. 7. This leaves a slight clearance between the wrapper and the underside of the upper paper grips for the lateral movement o the loaf when being carried b the transfer carria hereinbefore to a position. slight y above the loaf supporting table.

The movement of the feeding carriage from its normal position, see Fig. 4, to the delivery of the loaf above the initial folders, see Fig. 7, and the return again of the feeding carriage to its normal position, takes To relieve the cam of' place during the revolution of the cam it". part of its effort in raising the feeding carriage from its normal position, we have extended the long arm of the bell crank lever beyond its fulcrum 8", and have provided it with a counterbalance t of suficient weight to equalize the weight of the carriage, its load and its related parts;

During the ascending movement of the feeding carriage the loaf is pushed past the ihitial folders u", 1:", which then engage the wrapper and press it against the two vertical sides and stretch it tightly across the top.

The initialfolder u and a set ofiadjustable fingers y" are unitedly movable with the transfer carriage m, the initial folder u" in its normal position, see Fig. 6, being slightly clear of the path 'of the loaf but close enough to the path to engage the wrapperas the loaf' moves past it and press the wrapper against the adjacent sides of the loaf.

The folder c" is spring-tensioned and is hinged to the loaf supporting table 7'" to slightly overhang the ath of the loaf as it ascends, so that 1t will bear against the adjacent side of the loaf and press the wrapper to it, and then press the loaf against the backsupport w" for thepurpose of holding the loa in a suspended position when the feeding carriage recedes As the feeding carriage recedes from the limit of its upward movement, the initial folder u", starts its lateral movement across the feeding carriage path, and, as shown in Fig. 7 presses the own hang of the wrapper at the adiacent side across the bottomof the loaf, the loaf during this movement of the initial folder u", being held stationary against the back support w by the other initial folder 'v. a

When the initial folder M has passed fully across the bottom of the loaf, the adjustable fingers 3 move through the registering slots 2 in the back support w", see Fig. 23, and engaging the adjacent side of the loaf push it toward the loaf support-ing table 1'. During this movement of the initial folder u", the initial folder "1:" gives way to allow the movable initial folder to pass it, but in giving way, it maintains a pressure upon the wrapper and the loaf, and spreads the downhang of the adjacent side of the wrapper against the bottom side of the loaf, and at the same time draws the wrapper tightly around the other three sides.

When the loaf is pushed to its limit of movement by the adjustable fingers y, it comes into position with the presser plate 9 as shown in Fig. 3, but before the presser plate a descends, to engage the loaf, two

lifters b operated. by a cam c raise the partly wrapped loaf above the surface of recedes frombeneath'it, to prevent the initial folder u' from loosenin the wrapper.

When the initial fol er u" has receded from beneaththe loaf, the lifters 6 return to a normal position, as shown in Fig. 7, and

To effect a positive motion of the presser plate a we have provided it with a bell crank lever d fulcrumed to an arm e supported from' some convenient part of t e main frame a, and we have provided the.

transfer carriage m" with a cam foropcrating the bell crank lever d, t e cam f having an inclined surface actuating the bell crank lever d to raise the presser plate as the transfer carriage moves forward, and to lower itas the transfer carriage recedes to a normal position. 3 During the forward movement of the transfer carriage, the presser plate a is lifted entirely clear of the loaf, so that there will be no possibility of the wrapper coming into contact with it. During the receding movement of the transfer carriage the'cam f 0 rates the bell crank lever d and lowerste presser plate against the top of the wrapper with suflicient pressure to hold the loaf firmly against the loaf supporting table, during the formation of the end folds. When the parts are in this position, the wrapper is of a tubular shape conforming to the bottom, top and vertical the initial folder a" and hold it in its elevated position until the said initial folder I sides of the loaf and projecting beyond ends of the loaf sufliciently to form the end the folds, as shown in Fig. 25.

The end folders, which move in unison wit-h the feeding carriage, rise as the feeding carriage elevates the next loaf, and these end folders come into contact with the projecting ends of the wrapper and fold them to lie smoothly and evenly against the end of the wrapped package. As these end folders complete, in a'single movement, the forma-' tionof the end folds, we will, before describing the actuating mechanism, explain, how

I they tuck and fold the ends of the wrapper to the required shape.

Each end folder consists of a substantially rectangular plate k, to the top of which is hinged a triangular plate Z The rectangular plate 70* moves in a plane substantially parallel with theerid of the loaf, and the triangular plate Z normally occupies an inclined position with relation to the rectangular plate k. As the end folders rise with the feeding carriage, the top edge of the rectangular plate k comes into contact with the bottom side of the wrapper, and, being of substantially the same. width as the loaf, folds the bottom side of the wrapper to lie evenly against the end of the loaf andparallel with the edges thereof as indicated at 6 angular shape and the top of the wrappersubst-antially flat, and it is when the rectangular plate is in this position that the triangular plate Z 'which we will hereafter call the hinged. member is moved into the same. vertical plane as the rectangular plate.

i As'the hinged member Z assumes a vertical position, it presses against the top of the wrapper, and, bending it into a vertical plane, forms it to a triangular shape and draws what was previouslythe vertical sides of the wrapper tightly across the ends of the loaf, as shown in Fig. 27. l'Vhen the parts have attained the limit of movement in this position, the end fold is completely shaped with the peak a? of the fold in a substantially perpendicular position, and the apex of the fold is ready to be turned down against the end of the package and sealed thereto.

The fold-forming action of the end folder may be briefiy summarized as follows -The rectangular plate is, being one of the fold forming elements, exteriorly engages one side of the wrapper and folds it smoothly and evenly against the article contained therein, and as it continues its advance to its limit of movement, enters interiorly of the remaining sides of the wrapper 'to define the lines along which the remainder of the end'folds' are to be made, and when it has fully entered within the remaining sides of the wrapper, it serves as a former and a support for the. wrapper sides during the formation of the. folds thereof! The-hinged- ,member also enters interiorly of the wrapper sides, and when moved into the same plane. as the rectangular plate interiorly en-- gages the remaining wrapper sides, and, by

tensionmg them, effects the formation of the folds along the line definedby the foldforming elementlc. It is possible to modify" the construction of the end folderwithin the scope of the appended claims without departing fromthe principle of the invention or the result attained from the use thereof. Owing to the frangible character of the paper, we find it advisable to construct each of the end folders of the two parts 7;; and Z, so that the rectangular plates 70 will prepare theend folds to be completed by the triangular or hinged members, which engage the material at an angle of about thirty degrees from the perpendicular and thus avoid breaking it. These hinged members.

are then straightened out into the same plane as the rectangular plates by the oscillating members d*, which operate to pass across the outer side faces of the end folders when the latter have attained their limit ofmotion. v I In some classes of wrappers, especially those which are not readily tearable, we may make the triangular plates integral parts of the rectangular plates and in such' cases, and when the adjacent edges of thepeak of the end folds are not intended to overlap, the oscillating membersjgi may be dispensed with. I

life will describe in detail the construction and operation of the end folders and oscillating members (Z later on? U When the hinged members Z h-ave been straightened into the same plane as the ice "rectangular plates 10. ereasers e are moved transversely across the end folds while the end folders are contained therein, to press the gummed edges f together and crease the edges g, h. in Figs. 11 and 19, are provided with tensioned arms 2'", and these arms are hinged tolevers j". The levers are fulcrumed on studs 94:, held by brackets Z tb part of the main frame a", and these studs k are pr vided withcranks m connected by universal links 0 to a rock shaft p oscillated by a roller connectiong from the cam 1' on the cam shaft h. The cam 1' 'is so timed that These creasers e as shown when the formation of the endfolds is com- 

